Why the Entropy of a Black Hole is
- 24 April 1995
- journal article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 74 (17) , 3319-3322
- https://doi.org/10.1103/physrevlett.74.3319
Abstract
A black hole considered as a part of a thermodynamical system possesses the Bekenstein-Hawking entropy $S_H =A_H /(4l_{\mbox{\scriptsize{P}}}^2)$, where $A_H$ is the area of a black hole surface and $l_{\,\mbox{\scriptsize{P}}}$ is the Planck length. Recent attempts to connect this entropy with dynamical degrees of freedom of a black hole generically did not provide the universal mechanism which allows one to obtain this exact value. We discuss the relation between the 'dynamical' contribution to the entropy and $S_H$, and show that the universality of $S_H$ is restored if one takes into account that the parameters of the internal dynamical degrees of freedom as well as their number depends on the black hole temperature.Comment: 11 pages, Alberta Univ. Preprint Alberta-Thy-22-9
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